A new study from the University of Geneva points to the brain’s waste-clearance system — the glymphatic system — as a possible piece of the psychosis puzzle. In people with 22q11.2 deletion syndrome, a high-risk genetic condition, researchers found developmental differences in an MRI-derived marker linked to glymphatic function, along with associations to hippocampal excitation/inhibition balance and psychosis vulnerability.

A team from UNIGE shows that early alterations in the brain’s clearance system could contribute to vulnerability to psychosis.

How can we explain the onset of psychotic symptoms characteristic of schizophrenia? Despite their major and often irreversible impact on intellectual abilities and autonomy, the biological mechanisms that precede their emergence remain poorly understood. A team from the Department of Psychiatry at the Faculty of Medicine and the Synapsy Center for Neuroscience Research in Mental Health at the University of Geneva (UNIGE) provides new insight into this question. Early dysfunction of the glymphatic system, the network responsible for removing waste from the brain, could be a key vulnerability factor. This research has been published in Biological Psychiatry: Global Open Science.

Hallucinations and delusions are among the characteristic psychotic symptoms of schizophrenia spectrum disorders, which may also be accompanied by social withdrawal and cognitive decline. These disorders, considered neurodevelopmental conditions, most often emerge during adolescence or early adulthood and have an estimated prevalence of 0.5–3% in the general population.

This study broadens the phenotypic and genetic spectrum of PNH, demonstrating a dual PNH phenotype associated with a bi‑transcript mechanism and mosaic inheritance, including tissue‑specific mosaicism.

PNH is a neurodevelopmental brain malformation characterized by failure of the gray matter to properly migrate to the cerebral cortex during embryonic development. This results in ectopic localization around the ventricular ependyma.¹ MRI serves as the primary diagnostic tool, showing bilateral periventricular gray matter nodules with a signal intensity similar to that of normal cortical gray matter.^2,3 Its primary clinical manifestation is epilepsy, which is often accompanied by intellectual disabilities and learning difficulties.^2,3 PNH is genetically heterogeneous and is linked to variants in multiple genes, including ARFGEF2, ERMARD, NEDD4L, ARF1, and MAP1B, as well as abnormalities in chromosome 5. Among these, pathogenic variants in FLNA are the most common genetic causes.⁴

FLNA is located at Xq28 and comprises 47 exons,⁵ encoding a 280 kDa actin binding protein, called filamin A. The N-terminal region contains an actin binding domain (ABD) and a rod-like structure composed of 24 immunoglobulin-like repeats. ABD interacts with actin to stabilize the cytoskeletal architecture and plays crucial roles in maintaining cell shape, migration, and transmitting mechanical force. FLNA regulates cellular migration and extension processes via interactions with several signaling proteins, including small GTPases Rac/Rho, TRAF2, integrins, and BRCA2.^6–8 This gene possesses at least 2 transcription initiation sites (ENST00000369850.8 and ENST00000610817.4) that use distinct promoters and demonstrate tissue-specific expression.^6–8 Rat FLNA-knockdown models exhibit impaired neuronal migration and elevated epileptic susceptibility.